Exploring the Efficacy of a Safe Cryotherapy Alternative: Physiological Temperature Changes From Cold-Water Immersion Versus Prolonged Cooling of Phase-Change Material

in International Journal of Sports Physiology and Performance

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Susan Y. Kwiecien
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Malachy P. McHugh
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Stuart Goodall
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Kirsty M. Hicks
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Angus M. Hunter
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Glyn Howatson
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DOI:
https://doi.org/10.1123/ijspp.2018-0763
Keywords:
recovery; thermoregulation; cold therapy; hydrotherapy; ice bath
In Print:
Volume 14: Issue 9
Page Range:
1288–1296
Restricted access

Purpose: To evaluate the effectiveness between cold-water immersion (CWI) and phase-change-material (PCM) cooling on intramuscular, core, and skin-temperature and cardiovascular responses. Methods: In a randomized, crossover design, 11 men completed 15 min of 15°C CWI to the umbilicus and 2-h recovery or 3 h of 15°C PCM covering the quadriceps and 1 h of recovery, separated by 24 h. Vastus lateralis intramuscular temperature at 1 and 3 cm, core and skin temperature, heart-rate variability, and thermal comfort were recorded at baseline and 15-min intervals throughout treatment and recovery. Results: Intramuscular temperature decreased (P < .001) during and after both treatments. A faster initial effect was observed from 15 min of CWI (Δ: 4.3°C [1.7°C] 1 cm; 5.5°C [2.1°C] 3 cm; P = .01). However, over time (2 h 15 min), greater effects were observed from prolonged PCM treatment (Δ: 4.2°C [1.9°C] 1 cm; 2.2°C [2.2°C] 3 cm; treatment × time, P = .0001). During the first hour of recovery from both treatments, intramuscular temperature was higher from CWI at 1 cm (P = .013) but not 3 cm. Core temperature deceased 0.25° (0.32°) from CWI (P = .001) and 0.28°C (0.27°C) from PCM (P = .0001), whereas heart-rate variability increased during both treatments (P = .001), with no differences between treatments. Conclusions: The magnitude of temperature reduction from CWI was comparable with PCM, but intramuscular temperature was decreased for longer during PCM. PCM cooling packs offer an alternative for delivering prolonged cooling whenever application of CWI is impractical while also exerting a central effect on core temperature and heart rate.

Kwiecien and McHugh are with the Nicholas Inst of Sports Medicine and Athletic Trauma, Lenox Hill Hospital, New York, NY. Kwiecien, McHugh, Goodall, Hicks, and Howatson are with the Dept of Sport, Exercise and Rehabilitation, Northumbria University, Newcastle upon Tyne, United Kingdom. Hunter is with the Physiology, Exercise and Nutrition Research Group, University of Stirling, Scotland, United Kingdom. Howatson is with the Water Research Group, North West University, Potchefstroom, South Africa.

Kwiecien (susan@nismat.org) is corresponding author.
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